Hermetic seal and a method of assembling

ABSTRACT

A hermetic seal between an optical element and a metal mount or housing using a fluoropolymer. The fluoropolymer is dispersed along the interior edge of the metal mount. The metal mount and fluoropolymer are then heated to a temperature exceeding the melting point of the fluoropolymer. Once heated the optical element is pressed into the metal mount and allowed to cool. The metal mount, optical element and thickness of fluoropolymer are sized to provide an interference fit between the metal mount and optical element.

CROSS-REFERENCE TO PENDING APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/830,951 filed Dec. 4, 2017, (U.S. Pat. No. 10,151,920), which was acontinuation of U.S. patent application Ser. No. 14/681,650, (U.S. Pat.No. 9,835,855), which claimed the benefit of U.S. ProvisionalApplication No. 61/976,905, filed Apr. 8, 2014, all of which areincorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates generally to method for sealing an opticalelement to a metal housing. More particularly, the present inventionrelates to a method for providing a moisture tight seal between anoptical element and a metal frame capable of withstanding multiplecycles of sterilization in an autoclave.

BACKGROUND OF THE INVENTION

Many medical procedures have been improved over the past decades by theuse of arthroscopic devices. Treatments that once required invasiveprocedures and extended hospital stays are routinely done on anoutpatient basis with an abbreviated recovery period. Endoscopes aloneand in combination with imaging systems are used for arthroscopy as wellas other diagnostic procedures. The endoscopes and optical couplerssometimes used to connect the endoscope to an imaging system must besterilized before they can be used in an evasive procedure.

The most common, quickest, and cost effective way to sterilize a pieceof equipment is to use an autoclave. This subjects the tool to a highpressure, high temperature and high moisture environment proven toeffectively kill pathogens.

The surfaces of the optical elements used in these tools should have nodebris or substance on them that will obscure or degrade the quality ofthe image they are transmitting. The optical elements are positionedwithin a metal tube or sheath and isolated from the environment bysealing the ends of the sheath. Typically, an optical element withmetalized edges is used to seal the ends of the sheath or tube. Themetalized edges of the optical element are brazed or soldered into thesheath or tube to form the hermetic seals.

As can be imagined subjecting these optical tools to the environmentinside of an autoclave can be detrimental to its longevity if moisturewere to breach the hermetic seals. If sufficient moisture penetrates theseals to allow condensation on the internal surfaces of the opticalelement it will distort the view provided by the optics. If the opticalelements contained within the sheath can be chemically attacked bymoisture that has condensed on their surfaces the distortion to the viewwill be permanent and remain if the condensation dissipates.

Various methods of securing an optical element in an autoclavableoptical tool are known. These include braising, flitting, O-rings,adhesive and brazing. However, each of these methods have theirdisadvantages. These disadvantages range from cost and labor required toshort life cycles.

What is needed is a method for mounting an optical element or windowinto an optical train that is quick, inexpensive, easy to assemble andprovides a reasonable life cycle.

BRIEF SUMMARY OF THE INVENTION

The present invention achieves its objectives by providing a hermeticseal between an optical element and a metal mount or housing using afluoropolymer. The fluoropolymer is dispersed along the interior edge ofthe metal mount or on the optical element. The metal mount andfluoropolymer are then heated to a temperature exceeding the meltingpoint of the fluoropolymer. Once heated the optical element is pressedinto the metal mount and allowed to cool. The metal mount, opticalelement and thickness of fluoropolymer our sized to provide aninterference fit between the metal mount and optical element.

The present invention may be used in various configurations includingthe metal mount is part of the tubular metal housing forming the opticaltrain or where the optical element mounted in the metal mount is furthersecured to a tubular metal housing by brazing or welding the metal mountto the metal housing.

The present invention provides an inexpensive, effective and rigorousway to mount optical elements for application where it will be subjectedto autoclave sterilization or where containing or excluding water ormoisture is desired.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention will now be described in furtherdetail. Other features, aspects, and advantages of the present inventionwill become better understood with regard to the following detaileddescription, appended claims, and accompanying drawings (which are notto scale) where:

FIG. 1 is a progression of the drawings showing the preferred embodimentof the present invention used on an optical element;

FIG. 2 is a progression of the drawings showing another embodiment ofthe present invention used on an optical element

FIG. 3 is a cross sectional view of one embodiment of the opticalelement mount of the present invention;

FIG. 4 is a cross sectional view of the optical element mount of FIG. 1secured in a metal housing;

FIG. 5 is a progression of the drawings showing the present inventionused on an optical element;

FIG. 6 is a progression of the drawings showing the present inventionused on a window;

FIG. 7 is a progression of drawings showing a cross sectional view ofanother embodiment of the optical element mount of the presentinvention;

FIG. 8 is a progression of drawings showing a cross sectional view ofanother embodiment of the optical element mount of the presentinvention;

FIG. 9 is a progression of drawings showing a cross sectional view ofanother embodiment of the optical element mount of the presentinvention; and

FIG. 10 is a progressive drawing showing a cross section view of anotherembodiment of the optical element mount of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides a cost effective and durable seal betweenan optical element 22 and metal mount 24 by using a crystalline orsemi-crystalline fluoropolymer, chioropolymer, fluorochloropolymer,copolymers of fluoropolymer, chloropolymer, and fluorochloropolymer orParylene N, a non-halogenated poly(para-xylene), that have high moisturebarrier properties and a crystalline melting point above 145° C. In thepreferred embodiment a ceramic, sapphire or glass optical element 22 isheld in a metal mount 24 by a fluoropolymer 26. The optical element 22is generally circular, but may be any regular or irregular shape. Themetal mount 24 surrounds the optical element. This metal mount 24 may bethe end portion of a tubular metal housing 30 that forms the opticaltrain 32 as seen in FIGS. 1, 2, 6, 7, and 10.

In other embodiments the metal mount 24 functions as a frame which holdsthe optical element 22. The metal mount 24 is then secured to a tubularmetal housing 30 by a weld 28 or brazed joint between the metal mount 24and the metal housing 30. See FIGS. 3, 4, 5 and 6 In other applicationsthe optical element 22 and metal mount 24 may be secured to the tubularmetal housing 30 by crimping the end of the metal housing 30 over theedge of the metal mount 4 and/or optical element 22.

In the preferred embodiment a fluoropolymer 26 including but not limitedto chlorotrifluoroethylene polymer, copolymer of tetrafluoroethylene andperfluoroalkoxyethylene, polyvinyl fluoride, Parylene C, Parylene D, andParylene HT, ETFE (Alternate names,poly(1,1,2,2-tetrafluorobutane-1,4-diyl),poly(ethene-co-tetrafluoroethene, ethylene tetrafluoroethylene) powdersuch as ETFE Powder Topcoat, clear or pigmented manufactured by E.I. duPont de Nemours & Company, Wilmington, Del.), is applied to the sealarea surface 34 of a metal mount 24. The ETFE powder can be applied byany number of methods including but not limited to, spreading orsuspension or paste of the ETFE power in a liquid carrier such asxylene, electrostatic deposition from a fluidized ETFE particle bed onto the heated seal area surface 34, or other know methods to depositthermoplastic coating to metal substrates. In addition to powder form,Fluoropolymers 26 in tape or sheet form may be used for the presentinvention.

The ETFE can be applied to the metal mount 24, optical element 22, orboth metal mount sealing area surface 34 and optical element's 22sealing surfaces 36. The ETFE powder coated sealing surfaces 34 and/or36 are heated in an oven to at about 285° C. for 10 to 15 minutes or aperiod of time sufficient to fuse the ETFE particles. After fussing theETFE to the sealing surfaces 34 and/or 36 the optical element 22 andmetal mount 24 are positioned such that they can be pressed together forform a seal when pressure is applied to either or both elements See FIG.1.

Prior to pressing the optical element 22 into the metal mounting 24,they are heated until the fluoropolymer melts (285° C.-325° C. for ETFEresin). When the fluoropolymer 26 melts pressure is applied to theoptical element 22 and/or metal mount 24 to push the optical element 22into the metal mount 24 forcing the viscous resin to flow over andcontact the optical element 22 and metal mount 24 on the seal surfaces34 and 36. After they are sealed they are allow to cool to roomtemperature.

In the preferred embodiment the uncoated clearance between the opticalelement 22 and metal mount 24 can range between 1 micron and 100 micronswith the optimum clearance between 7 microns and 25 microns. The appliedthickness of ETFE should be sufficient to form a continuous layer ofETFE between the two surfaces to be sealed. The combined thickness ofthe fused fluoropolymer 26 on the metal mount sealing surface 34 shouldbe between 5 microns and 500 microns thicker than the clearance betweenthe metal mount sealing surface 34 and optical mount sealing surface 36before the application of the resin.

One skilled in the art will recognize that the fluoropolymers 26 listedhave some level of permeability and that the width and thickness of theseal area will have some impact on the level hermeticity of the seal. Wehave found that seals having a width less than 100 microns and anaverage thickness of at least 15 microns will typically have a heliumleak rate between 1×10-9 to 1×10-8 atm.cc/sec and pass 500 autoclavecycles.

Seals made with substrates where one or both seal surfaces are at slightangle the to the to the direction of substrate insertion increase thepercentage of continuous seal area. Thus in one embodiment of theinvention the sealing surface 34 of the metal mount 24 is chamfered. Inthis embodiment the sealing surface 36 of the optical element 22 may bechamfered as well. The chamfer angle of these sealing surfaces 34 and 36would preferably be the same. See FIG. 2.

In another embodiment of the substrates are prepared as explained aboveare heated above the melting point of the fluoropolymer 26 and seatedtogether while one of the substrates was rotated between 15° and 90°perpendicular to the direction of insertion over the distance betweenwhere the resin layer of one substrate first made contact with the othersubstrate and where the maximum thickness of the seal is achieved. Thistwisting action increase the amount of and introduces a second directionof shear experienced by the molten resin, increasing the amount ofintimate contact between the resin and substrates.

Other embodiments of the present invention start by applying a primercoat 20 to the interior surface of the metal mount 24 and the peripheraledge of the optical element 22. This involves applying a dispersion of afluoropolymer 26 to the interior surface of the metal mount 24 and theperipheral edge of the optical element 22. The metal mount 24 andoptical element 22 are then heated to above the melting point of thefluoropolymer to adhere the primer coat to the metal mount 24 and theoptical element 22. It is heated within a range of 285° to 325° C. for atime sufficient to sinter the deposited primer particles.

The optical element 22 and metal mount 24 are allowed to cool. A film ortape of fluoropolymer material 3 is wrapped around the exteriorperipheral edge of the optical element 22. The metal mount 24 is thenheated rapidly to a temperature within a range of 285° to 325° C. in anon-oxidative atmosphere or vacuum. The optical element 22 is thenpressed into the metal mount 24 by a mechanical means. The thickness ofthe fluoropolymer 26 is in excess of the amount sufficient to provide aninterference fit between peripheral edge of the optical element 22 andthe interior of the metal mount 24 and hold the optical element 22 inplace.

Once the optical element 22 is secured in the metal mount 24, theassembly can be inserted into a metal housing 30 of an endoscope orother optical device. The assembly is secured to the tubular metalhousing 30 by a weld 28 along the interface between the metal mount 24and the metal housing 30.

The present invention can also be adapted to installing an opticalelement 22 directly into the tubular metal housing 30 or a tube mount.See FIG. 7. In this embodiment the primer coat 20 is applied directly tothe interior of the metal mount 24 of the tubular metal housing 30 andthe outer periphery of the optical element 22. These parts are thenheated to a temperature above the melting point of the fluoropolymerprimer. The pieces are allowed to cool. Once cooled the exteriorperiphery of the optical element 22 is wrapped with a film or tape offluoropolymer 26. The optical element 22 is then pressed into aninterference fit in the metal mount 24 of the tubular metal housing 30.

The tube mount shown in FIG. 7 can be further improved by crimping theends of the tube mount down over the fluoropolymer 26 and the outerperipheral edge of the optical element 22. See FIG. 8. This ensures theoptical element 22 is retained in the tube mount.

FIG. 9 shows another embodiment of the present invention. Here theoptical element 22 is mounted in the metal mount 24 as first explainedabove. A second ring 38 is placed around the outer periphery of themetal mount 24. The metal mount 24 extends across the fluoropolymer 26and onto the first face of the optical element 22. The second ring 38extends across the metal mount 24, fluoropolymer 26 and on to theopposing or second face of the optical element 22. This assembly is thensecured to the metal housing 30 by a first weld 28 located at theinterface of the metal mount 24 and the second ring 38 and a second weld40 located at the interface between the second ring 38 and the metalhousing 30.

FIG. 10 shows another embodiment of the present invention. In thisembodiment no primer coat is applied to the metal mount 24 of thetubular metal housing 30 or the outer periphery of the optical element22. The periphery of the optical element 22 is wrapped with afluoropolymer tape or film 26, formed by coating the edges of theoptical element 22 with a solvent solution or particle dispersion of oneof the herein polymer material of this invention. The metal mount 24 ofthe tubular metal housing 30 is heated to within a range of 285° to 325°C. in air, vacuum, or non-oxidizing atmosphere. The optical element 22is then pressed into an interference fit in the tube mount while thetube is within a range of 285° to 325° C. As soon as the optical element22 contacts the metal mount 24 of the tubular metal housing 30, themetal housing 30 is immediately removed from the heat source and allowto cool by convection.

The present invention has numerous benefits that are not possible withprior art methods for securing an optical element 22 into anautoclavable or hermetic device. The present invention allows forcoating of the optical element 22 before it is mounted.

If the mounted optical element 22 assembly of the present invention doesnot pass quality control requirements or is otherwise defective, theoptical element 22 may be removed from the mount 24 and reused.

Glass, quartz or sapphire optical elements may be mounted using thepresent invention.

The present invention does not require any machining once the opticalelement 22 is mounted.

Standard helium leak testing can be used to check the seal of thepresent invention mountings. More costly testing methods are notnecessary.

The interface between the optical element 22 and the housing or mountsis cushioned by the fluoropolymer material. This protects the opticalelement 22 from thermal shock during sterilization and mechanical shocksarising from mishandling of the assembly.

The finished assemblies are commonly used on medical devices.Fluoropolymers 26 as well as the materials used for the optical element22, metal mount 24 and metal housing 30 are all biocompatible. Thusrelated complications are avoided.

Finally the cross sectional area of the fluoropolymer 26 presented tothe face of the optical element 22 and optical train 32 and subjected tomoisture is much smaller than the area of a comparable O-ring seal. Thepresent invention also has a longer avenue of penetration for moistureto travel than comparable O-ring seals. Thus it is harder for moistureto penetrate the seal of the present invention than it is to penetratean O-ring seal. This results in reduced moisture penetration and alonger service life for the device.

Microscopic voids exist on the surfaces of both the metal mount 24 andoptical element 22. The ability of the material typically used forO-rings to fill these voids is limited by the elastic properties of theO-ring. Moisture can migrate through these the voids between theinterface of the O-ring and the tube and optical element.

The process of melting the fluoropolymer 26 in contact with the sealsurface 34 of the metal mount 24 and the seal surface 36 of the opticalelement 22 surfaces, combined with the low surface tension of the meltedfluoropolymer 26, results in the fluoropolymer 26 being able toeffectively wet and flow into these microscopic voids present on themetal mount 24 and optical element 22 surfaces. Filling and bonding tothe seal surface 34 and 36 voids by the molten fluoropolymer 26 preventsthe migration of moisture through the voids between the fluoropolymer26, metal mount 24 and optical element 22 interface.

The foregoing description details certain preferred embodiments of thepresent invention and describes the best mode contemplated. It will beappreciated, however, that changes may be made in the details ofconstruction and the configuration of components without departing fromthe spirit and scope of the disclosure. Therefore, the descriptionprovided herein is to be considered exemplary, rather than limiting, andthe true scope of the invention is that defined by the following claimsand the full range of equivalency to which each element thereof isentitled.

What is claimed is:
 1. A method for hermetically sealing an opticalelement of an arthroscopic device to a metal mount of the arthroscopicdevice, wherein a clearance between a sealing surface of the opticalelement and a sealing surface of the metal mount is in a range of 1microns to 100 microns, said method comprising: applying a fluoropolymerincluding ethylene tetrafluoroethylene to the sealing surface of themetal mount; heating the fluoropolymer and the metal mount to atemperature above the fluoropolymer's melting point, in a range of about285° C. to about 325° C.; and pressing an optical element into the metalmount; wherein a thickness of fluoropolymer is sized to provide ahermetic seal between the optical element and the metal mount.
 2. Themethod of claim 1, further comprising: rotating the optical elementrelative to the metal mount as the optical element is pressed into themetal mount.
 3. The method of claim 2, further comprising: the rotatingbeing in a range of 15° to 90° relative to the metal mount.
 4. Themethod of claim 1, wherein the hermetic seal has a helium leak ratebetween 1×10-9 to 1×10-8 atm.cc/sec.
 5. The method of claim 1, furthercomprising retaining the fluoropolymer and the metal mount within therange of 285° C. to 325° C. for 10 to 15 minutes.
 6. The method of claim1, further comprising: cooling the optical element, metal mount andfluoropolymer to room temperature.
 7. The method of claim 1, furthercomprising: chamfering the sealing surface of the metal mount; andchamfering the sealing surface of the optical element.
 8. The method ofclaim 7, wherein the angle of chamfer of the sealing surface of themetal mount is the same as the angle of chamfer of the sealing surfaceof the optical element.
 9. The method of claim 1, wherein the clearanceis in a range of 5 microns to 30 microns.
 10. The method of claim 1,further comprising: providing a thickness of the fluoropolymer on thesealing surface of the metal mount between 5 microns and 500 micronsthicker than the clearance between the sealing surface of the metalmount and the sealing surface of the optical element.
 11. Anarthroscopic device comprising: an optical element having a sealingsurface; a metal mount having a sealing surface and surrounding theoptical element, a clearance between the sealing surface of the opticalelement and the sealing surface of the metal mount being in a range of 1micron to 100 microns; and a hermetic seal comprising a fluoropolymerdisposed in the clearance between the sealing surface of the opticalelement and the sealing surface of the metal mount, the fluoropolymerincluding ethylene tetrafluoroethylene; wherein during assembly thefluoropolymer and the metal mount are heated to a temperature above amelting point of the fluoropolymer, in a range of about 285° C. to about325° C.
 12. The arthroscopic device of claim 11, wherein the hermeticseal has a helium leak rate between 1×10-9 to 1×10-8 atm.cc/sec.
 13. Thearthroscopic device of claim 11, wherein the clearance is in a range of5 microns to 30 microns.
 14. The arthroscopic device of claim 11,wherein after application of the fluoropolymer, a thickness of thefluoropolymer on the metal mount sealing surface being in a range of 5microns and 500 microns thicker than a clearance between the sealingsurface of the metal mount and the sealing surface of the opticalelement prior to the application of the fluoropolymer.
 15. Thearthroscopic device of claim 11, further comprising: the sealing surfaceof the optical element being chamfered; and the sealing surface of themetal mount being chamfered.
 16. The arthroscopic device of claim 11,further comprising: a metal housing, the metal mount being part of themetal housing.
 17. The arthroscopic device claim 16, further comprising:the metal mount being secured by one of a weld or a crimp to the metalhousing forming an optical train.
 18. An arthroscopic device comprising:an optical element having a sealing surface; a metal mount having asealing surface and surrounding the optical element, a clearance betweenthe sealing surface of the optical element and the sealing surface ofthe metal mount being in a range of 1 micron to 100 microns; and ahermetic seal comprising a fluoropolymer disposed in the clearancebetween the sealing surface of the optical element and the sealingsurface of the metal mount; the fluoropolymer being selected from thegroup consisting of: fluorochloropolymer, copolymers of fluoropolymer,Parylene N, non-halogenated poly(para-xylene), chlorotrifluoroethylenepolymer, copolymer of tetrafluoroethylene perfluoroalkoxyethylene,polyvinyl fluoride, Parylene C, Parylene D, and Parylene HT; whereinduring assembly the fluoropolymer and the metal mount are heated to atemperature above a melting point of the fluoropolymer, in a range ofabout 285° C. to about 325° C.; and wherein after application of thefluoropolymer, a thickness of the fluoropolymer on the metal mountsealing surface being in a range of 5 microns and 500 microns thickerthan a clearance between the sealing surface of the metal mount sealingsurface and the sealing surface of the optical element prior to theapplication of the fluoropolymer; and wherein the hermetic seal has ahelium leak rate between 1×10-9 to 1×10-8 atm.cc/sec.